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Transceiver (Continued) 3.2.5 Line Interface

W dokumencie DP8344B-2 (Stron 59-62)


3.0 Transceiver (Continued) 3.2.5 Line Interface 3270 Line Interface

In the 3270 environment, data is transmitted between a con­

trol unit and a device via a single coax cable or twisted pair cable. The coax type is RG62AU with a maximum length of 1.5 kilometers. The twisted pair cable has become more prevalent to reduce cabling and routing costs. Typically, a 24 AWG unshielded twisted pair is used to achieve the cost reduction goals. The length of the twisted pair cable is a minimum of 100 feet to a maximum of 900 feet. The 3270 protocol utilizes a transformer to isolate the peripheral from the cabling system.

An effective line interface design must be able to accept either coax or twisted pair cabling and compensate for noise, jitter and reflections in the cabling system. There must be an adequate amount of jitter tolerance to offset the effects of filtering and noise. Some filtering is needed to reduce ambient noise caused by surrounding hardware.

Such filtering must not introduce transients that the receiver comparator translates into data jitter.

An effective driver design should also attempt to compen­

sate for the filtering effects of the cable. Higher data fre­

quencies become attenuated more than lower frequency signals as cable length is increased, yielding greater dispari­

ty in the amplitudes of these signals. This effect generates greater jitter at the receiver. The 3270 signal format allows for a high voltage (predistorted) magnitude and a low volt­

age (nondistorted) magnitude within each data bit time. In­

creasing the predistorted-to-nondistorted signal level ratio counteracts the filtering phenomenon because the lower frequency signals contain less predistortion than do higher frequency signals. Thus, the amplitude of the higher fre­

quency signals is “ boosted” more than the lower frequency signals. Unfortunately, a low signal level is more susceptible to reflection-induced errors at short cable length. Proper im­

pedance matching and slower edge rates must be utilized to eliminate as much reflection as possible at these lengths.

than a perfectly matched termination. Board layout should make the comparator lines as short as possible. Lines should be placed closely together to avoid the introduction of differential noise. These lines should not pass near

“ noisy” lines. A ground plane should isolate all “ noisy”


BCP Design

The line interface design for the receiver is shown in Figure 3-12. An offset of approximately 17 mV separates the com­

parator inputs, making the receiver more immune to ambi­

ent noise present on the circuit board. A 2:1:1 (arranged as a 3:1) transformer increases any voltage sensitivity lost by introducing the offset. A bandpass filter is employed to re­

duce edge rate to the comparator and eliminate ambient noise. The bandwidth (30 kHz to 30 MHz) was chosen to provide sufficient attenuation for noise while producing mini­

mum data jitter.

The driver design, Figure 3-13, incorporates a National Semiconductor DS3487 and a resistor network to generate the proper signal levels. The predistorted-to-nondistorted ratio was chosen to be about 3 to 1. The coax/twisted pair front end, Figure 3-14, includes an ADC brand connector to switch between coax and twisted pair cable. The coax inter­

face has the shield capacitively coupled to ground. The 51 on resistor and the filter loading produce a termination of about 95ft. The twisted pair interface balances both lines and possesses an input impedance of about 100ft. This termination is somewhat higher than the characteristic im­

pedance (about 96ft) of twisted pair. Terminations of this type produce reflections that do not tend to generate mid-bit errors. Such terminations have the benefit of creating a larg­

er voltage at the receiver over longer cable lengths. For a more detailed explanation of the 3270 line interface, see Application Note “ A Combined Coax/Twisted Pair 3270 Line Interface for the DP8344 Biphase Communications Processor” . 5250 Line Interface Additionally, shielded or balanced operation must be ade­

quately supported. Shielded operation implies the use of coax cable, where balanced implies the use of twisted pair cable. Proper termination should be employed, and a termi­

nation slightly greater than the characteristic impedance of theline may actually provide more desirable waveforms

The 5250 environment utilizes twinax in a multi-drop config­

uration, where eight devices can be “ daisy-chained” over a total distance of 5,000 feet and eleven splices, (each physi­

cal device is considered a splice). Twinax connectors are bulky and expensive, but are very sturdy. Twinaxial cable is a shielded twisted pair that is nearly 1/3 of an inch thick.


® To coax/twisted pair front end

® To line driver circuitry

© To BCP comparator

* Includes board capacitance

3.0 Transceiver



© To 2:1:1 Transformer

® ■ From DP0344 Outputs

FIGURE 3-13. BCP Driver Design

T L / F / 9 3 3 6 -G 3

FIGURE 3-14. BCP Coax/Twisted Pair Front End The cable shield must be continuous throughout the trans­

mission system, and be grounded at the system unit and each station. Since twinax connectors have exposed metal connected to their shield grounds, care must be taken not to expose them to noise sources. The polarity of the two inner conductors must also be maintained throughout the trans­

mission system.

The transmission system is implemented in a balanced cur­

rent mode; every receiver/transmitter pair is directly cou­

pled to the twinax at all times. Data is impressed on the transmission line by unbalancing the line voltage with the driver current. The system requires passive termination at both ends of the transmission line. The termination resist­

ance value is given by:

Rt = Z o /2i where Rt: Termination Resistance Zo: Characteristic Impedance

In practice, termination is accomplished by connecting both conductors to the shield via 54.90,1 % resistors; hence the characteristic impedance of the twinax cable of 1070 ±5%

at 1.0 MHz. Intermediate stations must not terminate the line; each is configured for “ pass-through” instead of “ ter­

minate” mode. Stations do not have to be powered on to pass twinax signals on to other stations; all of the receiver/

transmitter pairs are DC coupled. Consequently, devices must never output any signals on the twinax line during pow- er-up or down that could be construed as data, or interfere with valid data transmission between other devices.

Driver Circuits for the DP8344B

The transmitter interface on the DP8344B is sufficiently general to allow use in 3270, 5250, and 8-bit transmission systems. Because of this generality, some external hard­

ware is needed to adapt the outputs to form the signals necessary to drive the twinax line. The chip provides three signals: DATA-OUT, DATA-DIY and TX-ACT. DATA-OUT is biphase serial data (inverted). DATA-DLY is the biphase se­

rial data output (non-inverted) delayed one-quarter bit-time.

TX-ACT, or transmitter active, signals that serial data is be­

ing transmitted when asserted. DATA-OUT and DATA-DLY can be used to form the A and B phase signals with their three levels by the circuit shown in Figure 3-15. TX-ACT is used as an external transmitter enable. The BCP can invert the sense of the DATA-OUT and DATA-DLY signals by as­

serting [TIN] (TMR[3]i. This feature allows both 3270 and 5250 type biphase data to be generated, and/or utilization of inverting on non-inverting transmitter stages.

Drivers for the 5250 environment may not place any signals on the transmission system when not activated. The power- on and off conditions of drivers must be prevented from causing noise on the system since other devices may be in operation. Figure 3-15 shows a “ DC power good” signal enabling the driver circuit. This signal will lock out conduc­

tion in the drivers if the supply voltage is out of tolerance.

Twinax signals can be viewed as consisting of two distinct phases, phase A and phase B, each with three levels, off,

P 8 3 4 4 B

D P 8 3 4 4 B

high and low. The off level corresponds with 0 mA current being driven, the high level is nominally 62.5 mA, +20%

-3 0 % , and the low level is nominally 12.5 mA, +20%

-3 0 % . When these currents are applied to a properly ter­

minated transmission line the resultant voltages impressed at the driver are: off level is 0V, low level is 0.32V ±20%, high level is 1.6V ±20%. The interface must provide for switching of the A and B phases and the three levels. A bi- modal constant current source for each phase can be built that has a TTL level interface for the BCP.

Receiver Circuits

The pseudo-differential mode of the twinax signals make receiver design requirements somewhat different than the coax 3270 world. Hence, the analog receiver on the BCP is not well suited to receiving twinax data. The BCP provides both analog inputs to an on-board comparator circuit as well as a TTL level serial data input, DATA-IN. The sense of this serial data can be inverted by the BCP by asserting [RIN], (TMR[4]j.

The external receiver circuit must be designed with care to ensure reliable decoding of the bit-stream in the worst envi­

ronment. Signals as small as 100 mV must be detected. In order to receive the worst case signals, the input level switching threshold or hysteresis for the receiver should be nominally 29 mV ±20%. This value allows the steady state, worst case signal level of 100 mV ±66% of its amplitude before transitioning.

3.0 Transceiver


To achieve this, a differential comparator with complemen­

tary outputs can be applied, such as the National LM361.

The complementary outputs are useful in setting the hyster­

esis or switching threshold to the appropriate levels. The LM361 also provides excellent common mode noise rejec­

tion and a low input offset voltage. Low input leakage cur­

rent allows the design of an extremely sensitive receiver, without loading the transmission line excessively.

In addition to good analog design techniques, a low pass filter with a roll-off of approximately 1 MHz should be ap­

plied to both the A and B phases. This filter essentially con­

ducts high frequency noise to the opposite phase, effective­

ly making the noise common mode and easily rejectable.

Layout considerations for the LM361 include proper bypass­

ing of the ± 12V supplies at the chip itself, with as short as possible traces from the pins to 0.1 /xF ceramic capacitors.

Using surface mount chip capacitors reduces lead induc­

tance and is therefore preferable in this case. Keeping the input traces as short and even in length is also important.

The intent is to minimize inductance effects as well and standardize those effects on both inputs. The LM361 should have as much ground plane under and around it as possi­

ble. Trace widths for the input signals especially should be as wide as possible; 0.1 inch is usually sufficient. Finally, keep all associated discrete components nearby with short routing and good ground/supply connections.

For a more detailed explanation of the 5250 line interface, see application note “ Interfacing the DP8344 to Twinax."

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FIGURE 3-15.5250 Line Interface Schematic

W dokumencie DP8344B-2 (Stron 59-62)